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/* tc-crx.c -- Assembler code for the CRX CPU core. Copyright 2004, 2005, 2006, 2007, 2008, 2009 Free Software Foundation, Inc. Contributed by Tomer Levi, NSC, Israel. Originally written for GAS 2.12 by Tomer Levi, NSC, Israel. Updates, BFDizing, GNUifying and ELF support by Tomer Levi. This file is part of GAS, the GNU Assembler. GAS is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3, or (at your option) any later version. GAS is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with GAS; see the file COPYING. If not, write to the Free Software Foundation, 51 Franklin Street - Fifth Floor, Boston, MA 02110-1301, USA. */ #include "as.h" #include "safe-ctype.h" #include "dwarf2dbg.h" #include "opcode/crx.h" #include "elf/crx.h" /* Word is considered here as a 16-bit unsigned short int. */ #define WORD_SHIFT 16 /* Register is 4-bit size. */ #define REG_SIZE 4 /* Maximum size of a single instruction (in words). */ #define INSN_MAX_SIZE 3 /* Maximum bits which may be set in a `mask16' operand. */ #define MAX_REGS_IN_MASK16 8 /* Utility macros for string comparison. */ #define streq(a, b) (strcmp (a, b) == 0) #define strneq(a, b, c) (strncmp (a, b, c) == 0) /* Assign a number NUM, shifted by SHIFT bytes, into a location pointed by index BYTE of array 'output_opcode'. */ #define CRX_PRINT(BYTE, NUM, SHIFT) output_opcode[BYTE] |= (NUM << SHIFT) /* Operand errors. */ typedef enum { OP_LEGAL = 0, /* Legal operand. */ OP_OUT_OF_RANGE, /* Operand not within permitted range. */ OP_NOT_EVEN, /* Operand is Odd number, should be even. */ OP_ILLEGAL_DISPU4, /* Operand is not within DISPU4 range. */ OP_ILLEGAL_CST4, /* Operand is not within CST4 range. */ OP_NOT_UPPER_64KB /* Operand is not within the upper 64KB (0xFFFF0000-0xFFFFFFFF). */ } op_err; /* Opcode mnemonics hash table. */ static struct hash_control *crx_inst_hash; /* CRX registers hash table. */ static struct hash_control *reg_hash; /* CRX coprocessor registers hash table. */ static struct hash_control *copreg_hash; /* Current instruction we're assembling. */ const inst *instruction; /* Global variables. */ /* Array to hold an instruction encoding. */ long output_opcode[2]; /* Nonzero means a relocatable symbol. */ int relocatable; /* A copy of the original instruction (used in error messages). */ char ins_parse[MAX_INST_LEN]; /* The current processed argument number. */ int cur_arg_num; /* Generic assembler global variables which must be defined by all targets. */ /* Characters which always start a comment. */ const char comment_chars[] = "#"; /* Characters which start a comment at the beginning of a line. */ const char line_comment_chars[] = "#"; /* This array holds machine specific line separator characters. */ const char line_separator_chars[] = ";"; /* Chars that can be used to separate mant from exp in floating point nums. */ const char EXP_CHARS[] = "eE"; /* Chars that mean this number is a floating point constant as in 0f12.456 */ const char FLT_CHARS[] = "f'"; /* Target-specific multicharacter options, not const-declared at usage. */ const char *md_shortopts = ""; struct option md_longopts[] = { {NULL, no_argument, NULL, 0} }; size_t md_longopts_size = sizeof (md_longopts); /* This table describes all the machine specific pseudo-ops the assembler has to support. The fields are: *** Pseudo-op name without dot. *** Function to call to execute this pseudo-op. *** Integer arg to pass to the function. */ const pseudo_typeS md_pseudo_table[] = { /* In CRX machine, align is in bytes (not a ptwo boundary). */ {"align", s_align_bytes, 0}, {0, 0, 0} }; /* CRX relaxation table. */ const relax_typeS md_relax_table[] = { /* bCC */ {0xfa, -0x100, 2, 1}, /* 8 */ {0xfffe, -0x10000, 4, 2}, /* 16 */ {0xfffffffe, -0xfffffffe, 6, 0}, /* 32 */ /* bal */ {0xfffe, -0x10000, 4, 4}, /* 16 */ {0xfffffffe, -0xfffffffe, 6, 0}, /* 32 */ /* cmpbr/bcop */ {0xfe, -0x100, 4, 6}, /* 8 */ {0xfffffe, -0x1000000, 6, 0} /* 24 */ }; static void reset_vars (char *); static reg get_register (char *); static copreg get_copregister (char *); static argtype get_optype (operand_type); static int get_opbits (operand_type); static int get_opflags (operand_type); static int get_number_of_operands (void); static void parse_operand (char *, ins *); static int gettrap (char *); static void handle_LoadStor (char *); static int get_cinv_parameters (char *); static long getconstant (long, int); static op_err check_range (long *, int, unsigned int, int); static int getreg_image (reg); static void parse_operands (ins *, char *); static void parse_insn (ins *, char *); static void print_operand (int, int, argument *); static void print_constant (int, int, argument *); static int exponent2scale (int); static void mask_reg (int, unsigned short *); static void process_label_constant (char *, ins *); static void set_operand (char *, ins *); static char * preprocess_reglist (char *, int *); static int assemble_insn (char *, ins *); static void print_insn (ins *); static void warn_if_needed (ins *); static int adjust_if_needed (ins *); /* Return the bit size for a given operand. */ static int get_opbits (operand_type op) { if (op < MAX_OPRD) return crx_optab[op].bit_size; else return 0; } /* Return the argument type of a given operand. */ static argtype get_optype (operand_type op) { if (op < MAX_OPRD) return crx_optab[op].arg_type; else return nullargs; } /* Return the flags of a given operand. */ static int get_opflags (operand_type op) { if (op < MAX_OPRD) return crx_optab[op].flags; else return 0; } /* Get the core processor register 'reg_name'. */ static reg get_register (char *reg_name) { const reg_entry *reg; reg = (const reg_entry *) hash_find (reg_hash, reg_name); if (reg != NULL) return reg->value.reg_val; else return nullregister; } /* Get the coprocessor register 'copreg_name'. */ static copreg get_copregister (char *copreg_name) { const reg_entry *copreg; copreg = (const reg_entry *) hash_find (copreg_hash, copreg_name); if (copreg != NULL) return copreg->value.copreg_val; else return nullcopregister; } /* Round up a section size to the appropriate boundary. */ valueT md_section_align (segT seg, valueT val) { /* Round .text section to a multiple of 2. */ if (seg == text_section) return (val + 1) & ~1; return val; } /* Parse an operand that is machine-specific (remove '*'). */ void md_operand (expressionS * exp) { char c = *input_line_pointer; switch (c) { case '*': input_line_pointer++; expression (exp); break; default: break; } } /* Reset global variables before parsing a new instruction. */ static void reset_vars (char *op) { cur_arg_num = relocatable = 0; memset (& output_opcode, '\0', sizeof (output_opcode)); /* Save a copy of the original OP (used in error messages). */ strncpy (ins_parse, op, sizeof ins_parse - 1); ins_parse [sizeof ins_parse - 1] = 0; } /* This macro decides whether a particular reloc is an entry in a switch table. It is used when relaxing, because the linker needs to know about all such entries so that it can adjust them if necessary. */ #define SWITCH_TABLE(fix) \ ( (fix)->fx_addsy != NULL \ && (fix)->fx_subsy != NULL \ && S_GET_SEGMENT ((fix)->fx_addsy) == \ S_GET_SEGMENT ((fix)->fx_subsy) \ && S_GET_SEGMENT (fix->fx_addsy) != undefined_section \ && ( (fix)->fx_r_type == BFD_RELOC_CRX_NUM8 \ || (fix)->fx_r_type == BFD_RELOC_CRX_NUM16 \ || (fix)->fx_r_type == BFD_RELOC_CRX_NUM32)) /* See whether we need to force a relocation into the output file. This is used to force out switch and PC relative relocations when relaxing. */ int crx_force_relocation (fixS *fix) { if (generic_force_reloc (fix) || SWITCH_TABLE (fix)) return 1; return 0; } /* Generate a relocation entry for a fixup. */ arelent * tc_gen_reloc (asection *section ATTRIBUTE_UNUSED, fixS * fixP) { arelent * reloc; reloc = xmalloc (sizeof (arelent)); reloc->sym_ptr_ptr = xmalloc (sizeof (asymbol *)); *reloc->sym_ptr_ptr = symbol_get_bfdsym (fixP->fx_addsy); reloc->address = fixP->fx_frag->fr_address + fixP->fx_where; reloc->addend = fixP->fx_offset; if (fixP->fx_subsy != NULL) { if (SWITCH_TABLE (fixP)) { /* Keep the current difference in the addend. */ reloc->addend = (S_GET_VALUE (fixP->fx_addsy) - S_GET_VALUE (fixP->fx_subsy) + fixP->fx_offset); switch (fixP->fx_r_type) { case BFD_RELOC_CRX_NUM8: fixP->fx_r_type = BFD_RELOC_CRX_SWITCH8; break; case BFD_RELOC_CRX_NUM16: fixP->fx_r_type = BFD_RELOC_CRX_SWITCH16; break; case BFD_RELOC_CRX_NUM32: fixP->fx_r_type = BFD_RELOC_CRX_SWITCH32; break; default: abort (); break; } } else { /* We only resolve difference expressions in the same section. */ as_bad_where (fixP->fx_file, fixP->fx_line, _("can't resolve `%s' {%s section} - `%s' {%s section}"), fixP->fx_addsy ? S_GET_NAME (fixP->fx_addsy) : "0", segment_name (fixP->fx_addsy ? S_GET_SEGMENT (fixP->fx_addsy) : absolute_section), S_GET_NAME (fixP->fx_subsy), segment_name (S_GET_SEGMENT (fixP->fx_addsy))); } } gas_assert ((int) fixP->fx_r_type > 0); reloc->howto = bfd_reloc_type_lookup (stdoutput, fixP->fx_r_type); if (reloc->howto == (reloc_howto_type *) NULL) { as_bad_where (fixP->fx_file, fixP->fx_line, _("internal error: reloc %d (`%s') not supported by object file format"), fixP->fx_r_type, bfd_get_reloc_code_name (fixP->fx_r_type)); return NULL; } gas_assert (!fixP->fx_pcrel == !reloc->howto->pc_relative); return reloc; } /* Prepare machine-dependent frags for relaxation. */ int md_estimate_size_before_relax (fragS *fragp, asection *seg) { /* If symbol is undefined or located in a different section, select the largest supported relocation. */ relax_substateT subtype; relax_substateT rlx_state[] = {0, 2, 3, 4, 5, 6}; for (subtype = 0; subtype < ARRAY_SIZE (rlx_state); subtype += 2) { if (fragp->fr_subtype == rlx_state[subtype] && (!S_IS_DEFINED (fragp->fr_symbol) || seg != S_GET_SEGMENT (fragp->fr_symbol))) { fragp->fr_subtype = rlx_state[subtype + 1]; break; } } if (fragp->fr_subtype >= ARRAY_SIZE (md_relax_table)) abort (); return md_relax_table[fragp->fr_subtype].rlx_length; } void md_convert_frag (bfd *abfd ATTRIBUTE_UNUSED, asection *sec, fragS *fragP) { /* 'opcode' points to the start of the instruction, whether we need to change the instruction's fixed encoding. */ char *opcode = fragP->fr_literal + fragP->fr_fix; bfd_reloc_code_real_type reloc; subseg_change (sec, 0); switch (fragP->fr_subtype) { case 0: reloc = BFD_RELOC_CRX_REL8; break; case 1: *opcode = 0x7e; reloc = BFD_RELOC_CRX_REL16; break; case 2: *opcode = 0x7f; reloc = BFD_RELOC_CRX_REL32; break; case 3: reloc = BFD_RELOC_CRX_REL16; break; case 4: *++opcode = 0x31; reloc = BFD_RELOC_CRX_REL32; break; case 5: reloc = BFD_RELOC_CRX_REL8_CMP; break; case 6: *++opcode = 0x31; reloc = BFD_RELOC_CRX_REL24; break; default: abort (); break; } fix_new (fragP, fragP->fr_fix, bfd_get_reloc_size (bfd_reloc_type_lookup (stdoutput, reloc)), fragP->fr_symbol, fragP->fr_offset, 1, reloc); fragP->fr_var = 0; fragP->fr_fix += md_relax_table[fragP->fr_subtype].rlx_length; } /* Process machine-dependent command line options. Called once for each option on the command line that the machine-independent part of GAS does not understand. */ int md_parse_option (int c ATTRIBUTE_UNUSED, char *arg ATTRIBUTE_UNUSED) { return 0; } /* Machine-dependent usage-output. */ void md_show_usage (FILE *stream ATTRIBUTE_UNUSED) { return; } char * md_atof (int type, char *litP, int *sizeP) { return ieee_md_atof (type, litP, sizeP, target_big_endian); } /* Apply a fixS (fixup of an instruction or data that we didn't have enough info to complete immediately) to the data in a frag. Since linkrelax is nonzero and TC_LINKRELAX_FIXUP is defined to disable relaxation of debug sections, this function is called only when fixuping relocations of debug sections. */ void md_apply_fix (fixS *fixP, valueT *valP, segT seg) { valueT val = * valP; char *buf = fixP->fx_frag->fr_literal + fixP->fx_where; fixP->fx_offset = 0; switch (fixP->fx_r_type) { case BFD_RELOC_CRX_NUM8: bfd_put_8 (stdoutput, (unsigned char) val, buf); break; case BFD_RELOC_CRX_NUM16: bfd_put_16 (stdoutput, val, buf); break; case BFD_RELOC_CRX_NUM32: bfd_put_32 (stdoutput, val, buf); break; default: /* We shouldn't ever get here because linkrelax is nonzero. */ abort (); break; } fixP->fx_done = 0; if (fixP->fx_addsy == NULL && fixP->fx_pcrel == 0) fixP->fx_done = 1; if (fixP->fx_pcrel == 1 && fixP->fx_addsy != NULL && S_GET_SEGMENT (fixP->fx_addsy) == seg) fixP->fx_done = 1; } /* The location from which a PC relative jump should be calculated, given a PC relative reloc. */ long md_pcrel_from (fixS *fixp) { return fixp->fx_frag->fr_address + fixp->fx_where; } /* This function is called once, at assembler startup time. This should set up all the tables, etc that the MD part of the assembler needs. */ void md_begin (void) { const char *hashret = NULL; int i = 0; /* Set up a hash table for the instructions. */ if ((crx_inst_hash = hash_new ()) == NULL) as_fatal (_("Virtual memory exhausted")); while (crx_instruction[i].mnemonic != NULL) { const char *mnemonic = crx_instruction[i].mnemonic; hashret = hash_insert (crx_inst_hash, mnemonic, (void *) &crx_instruction[i]); if (hashret != NULL && *hashret != '\0') as_fatal (_("Can't hash `%s': %s\n"), crx_instruction[i].mnemonic, *hashret == 0 ? _("(unknown reason)") : hashret); /* Insert unique names into hash table. The CRX instruction set has many identical opcode names that have different opcodes based on the operands. This hash table then provides a quick index to the first opcode with a particular name in the opcode table. */ do { ++i; } while (crx_instruction[i].mnemonic != NULL && streq (crx_instruction[i].mnemonic, mnemonic)); } /* Initialize reg_hash hash table. */ if ((reg_hash = hash_new ()) == NULL) as_fatal (_("Virtual memory exhausted")); { const reg_entry *regtab; for (regtab = crx_regtab; regtab < (crx_regtab + NUMREGS); regtab++) { hashret = hash_insert (reg_hash, regtab->name, (void *) regtab); if (hashret) as_fatal (_("Internal Error: Can't hash %s: %s"), regtab->name, hashret); } } /* Initialize copreg_hash hash table. */ if ((copreg_hash = hash_new ()) == NULL) as_fatal (_("Virtual memory exhausted")); { const reg_entry *copregtab; for (copregtab = crx_copregtab; copregtab < (crx_copregtab + NUMCOPREGS); copregtab++) { hashret = hash_insert (copreg_hash, copregtab->name, (void *) copregtab); if (hashret) as_fatal (_("Internal Error: Can't hash %s: %s"), copregtab->name, hashret); } } /* Set linkrelax here to avoid fixups in most sections. */ linkrelax = 1; } /* Process constants (immediate/absolute) and labels (jump targets/Memory locations). */ static void process_label_constant (char *str, ins * crx_ins) { char *saved_input_line_pointer; argument *cur_arg = &crx_ins->arg[cur_arg_num]; /* Current argument. */ saved_input_line_pointer = input_line_pointer; input_line_pointer = str; expression (&crx_ins->exp); switch (crx_ins->exp.X_op) { case O_big: case O_absent: /* Missing or bad expr becomes absolute 0. */ as_bad (_("missing or invalid displacement expression `%s' taken as 0"), str); crx_ins->exp.X_op = O_constant; crx_ins->exp.X_add_number = 0; crx_ins->exp.X_add_symbol = (symbolS *) 0; crx_ins->exp.X_op_symbol = (symbolS *) 0; /* Fall through. */ case O_constant: cur_arg->X_op = O_constant; cur_arg->constant = crx_ins->exp.X_add_number; break; case O_symbol: case O_subtract: case O_add: cur_arg->X_op = O_symbol; crx_ins->rtype = BFD_RELOC_NONE; relocatable = 1; switch (cur_arg->type) { case arg_cr: if (IS_INSN_TYPE (LD_STOR_INS_INC)) crx_ins->rtype = BFD_RELOC_CRX_REGREL12; else if (IS_INSN_TYPE (CSTBIT_INS) || IS_INSN_TYPE (STOR_IMM_INS)) crx_ins->rtype = BFD_RELOC_CRX_REGREL28; else crx_ins->rtype = BFD_RELOC_CRX_REGREL32; break; case arg_idxr: crx_ins->rtype = BFD_RELOC_CRX_REGREL22; break; case arg_c: if (IS_INSN_MNEMONIC ("bal") || IS_INSN_TYPE (DCR_BRANCH_INS)) crx_ins->rtype = BFD_RELOC_CRX_REL16; else if (IS_INSN_TYPE (BRANCH_INS)) crx_ins->rtype = BFD_RELOC_CRX_REL8; else if (IS_INSN_TYPE (LD_STOR_INS) || IS_INSN_TYPE (STOR_IMM_INS) || IS_INSN_TYPE (CSTBIT_INS)) crx_ins->rtype = BFD_RELOC_CRX_ABS32; else if (IS_INSN_TYPE (BRANCH_NEQ_INS)) crx_ins->rtype = BFD_RELOC_CRX_REL4; else if (IS_INSN_TYPE (CMPBR_INS) || IS_INSN_TYPE (COP_BRANCH_INS)) crx_ins->rtype = BFD_RELOC_CRX_REL8_CMP; break; case arg_ic: if (IS_INSN_TYPE (ARITH_INS)) crx_ins->rtype = BFD_RELOC_CRX_IMM32; else if (IS_INSN_TYPE (ARITH_BYTE_INS)) crx_ins->rtype = BFD_RELOC_CRX_IMM16; break; default: break; } break; default: cur_arg->X_op = crx_ins->exp.X_op; break; } input_line_pointer = saved_input_line_pointer; return; } /* Get the values of the scale to be encoded - used for the scaled index mode of addressing. */ static int exponent2scale (int val) { int exponent; /* If 'val' is 0, the following 'for' will be an endless loop. */ if (val == 0) return 0; for (exponent = 0; (val != 1); val >>= 1, exponent++) ; return exponent; } /* Parsing different types of operands -> constants Immediate/Absolute/Relative numbers -> Labels Relocatable symbols -> (rbase) Register base -> disp(rbase) Register relative -> disp(rbase)+ Post-increment mode -> disp(rbase,ridx,scl) Register index mode */ static void set_operand (char *operand, ins * crx_ins) { char *operandS; /* Pointer to start of sub-opearand. */ char *operandE; /* Pointer to end of sub-opearand. */ expressionS scale; int scale_val; char *input_save, c; argument *cur_arg = &crx_ins->arg[cur_arg_num]; /* Current argument. */ /* Initialize pointers. */ operandS = operandE = operand; switch (cur_arg->type) { case arg_sc: /* Case *+0x18. */ case arg_ic: /* Case $0x18. */ operandS++; case arg_c: /* Case 0x18. */ /* Set constant. */ process_label_constant (operandS, crx_ins); if (cur_arg->type != arg_ic) cur_arg->type = arg_c; break; case arg_icr: /* Case $0x18(r1). */ operandS++; case arg_cr: /* Case 0x18(r1). */ /* Set displacement constant. */ while (*operandE != '(') operandE++; *operandE = '\0'; process_label_constant (operandS, crx_ins); operandS = operandE; case arg_rbase: /* Case (r1). */ operandS++; /* Set register base. */ while (*operandE != ')') operandE++; *operandE = '\0'; if ((cur_arg->r = get_register (operandS)) == nullregister) as_bad (_("Illegal register `%s' in Instruction `%s'"), operandS, ins_parse); if (cur_arg->type != arg_rbase) cur_arg->type = arg_cr; break; case arg_idxr: /* Set displacement constant. */ while (*operandE != '(') operandE++; *operandE = '\0'; process_label_constant (operandS, crx_ins); operandS = ++operandE; /* Set register base. */ while ((*operandE != ',') && (! ISSPACE (*operandE))) operandE++; *operandE++ = '\0'; if ((cur_arg->r = get_register (operandS)) == nullregister) as_bad (_("Illegal register `%s' in Instruction `%s'"), operandS, ins_parse); /* Skip leading white space. */ while (ISSPACE (*operandE)) operandE++; operandS = operandE; /* Set register index. */ while ((*operandE != ')') && (*operandE != ',')) operandE++; c = *operandE; *operandE++ = '\0'; if ((cur_arg->i_r = get_register (operandS)) == nullregister) as_bad (_("Illegal register `%s' in Instruction `%s'"), operandS, ins_parse); /* Skip leading white space. */ while (ISSPACE (*operandE)) operandE++; operandS = operandE; /* Set the scale. */ if (c == ')') cur_arg->scale = 0; else { while (*operandE != ')') operandE++; *operandE = '\0'; /* Preprocess the scale string. */ input_save = input_line_pointer; input_line_pointer = operandS; expression (&scale); input_line_pointer = input_save; scale_val = scale.X_add_number; /* Check if the scale value is legal. */ if (scale_val != 1 && scale_val != 2 && scale_val != 4 && scale_val != 8) as_bad (_("Illegal Scale - `%d'"), scale_val); cur_arg->scale = exponent2scale (scale_val); } break; default: break; } } /* Parse a single operand. operand - Current operand to parse. crx_ins - Current assembled instruction. */ static void parse_operand (char *operand, ins * crx_ins) { int ret_val; argument *cur_arg = &crx_ins->arg[cur_arg_num]; /* Current argument. */ /* Initialize the type to NULL before parsing. */ cur_arg->type = nullargs; /* Check whether this is a general processor register. */ if ((ret_val = get_register (operand)) != nullregister) { cur_arg->type = arg_r; cur_arg->r = ret_val; cur_arg->X_op = O_register; return; } /* Check whether this is a core [special] coprocessor register. */ if ((ret_val = get_copregister (operand)) != nullcopregister) { cur_arg->type = arg_copr; if (ret_val >= cs0) cur_arg->type = arg_copsr; cur_arg->cr = ret_val; cur_arg->X_op = O_register; return; } /* Deal with special characters. */ switch (operand[0]) { case '$': if (strchr (operand, '(') != NULL) cur_arg->type = arg_icr; else cur_arg->type = arg_ic; goto set_params; break; case '*': cur_arg->type = arg_sc; goto set_params; break; case '(': cur_arg->type = arg_rbase; goto set_params; break; default: break; } if (strchr (operand, '(') != NULL) { if (strchr (operand, ',') != NULL && (strchr (operand, ',') > strchr (operand, '('))) cur_arg->type = arg_idxr; else cur_arg->type = arg_cr; } else cur_arg->type = arg_c; goto set_params; /* Parse an operand according to its type. */ set_params: cur_arg->constant = 0; set_operand (operand, crx_ins); } /* Parse the various operands. Each operand is then analyzed to fillup the fields in the crx_ins data structure. */ static void parse_operands (ins * crx_ins, char *operands) { char *operandS; /* Operands string. */ char *operandH, *operandT; /* Single operand head/tail pointers. */ int allocated = 0; /* Indicates a new operands string was allocated. */ char *operand[MAX_OPERANDS]; /* Separating the operands. */ int op_num = 0; /* Current operand number we are parsing. */ int bracket_flag = 0; /* Indicates a bracket '(' was found. */ int sq_bracket_flag = 0; /* Indicates a square bracket '[' was found. */ /* Preprocess the list of registers, if necessary. */ operandS = operandH = operandT = (INST_HAS_REG_LIST) ? preprocess_reglist (operands, &allocated) : operands; while (*operandT != '\0') { if (*operandT == ',' && bracket_flag != 1 && sq_bracket_flag != 1) { *operandT++ = '\0'; operand[op_num++] = strdup (operandH); operandH = operandT; continue; } if (*operandT == ' ') as_bad (_("Illegal operands (whitespace): `%s'"), ins_parse); if (*operandT == '(') bracket_flag = 1; else if (*operandT == '[') sq_bracket_flag = 1; if (*operandT == ')') { if (bracket_flag) bracket_flag = 0; else as_fatal (_("Missing matching brackets : `%s'"), ins_parse); } else if (*operandT == ']') { if (sq_bracket_flag) sq_bracket_flag = 0; else as_fatal (_("Missing matching brackets : `%s'"), ins_parse); } if (bracket_flag == 1 && *operandT == ')') bracket_flag = 0; else if (sq_bracket_flag == 1 && *operandT == ']') sq_bracket_flag = 0; operandT++; } /* Adding the last operand. */ operand[op_num++] = strdup (operandH); crx_ins->nargs = op_num; /* Verifying correct syntax of operands (all brackets should be closed). */ if (bracket_flag || sq_bracket_flag) as_fatal (_("Missing matching brackets : `%s'"), ins_parse); /* Now we parse each operand separately. */ for (op_num = 0; op_num < crx_ins->nargs; op_num++) { cur_arg_num = op_num; parse_operand (operand[op_num], crx_ins); free (operand[op_num]); } if (allocated) free (operandS); } /* Get the trap index in dispatch table, given its name. This routine is used by assembling the 'excp' instruction. */ static int gettrap (char *s) { const trap_entry *trap; for (trap = crx_traps; trap < (crx_traps + NUMTRAPS); trap++) if (strcasecmp (trap->name, s) == 0) return trap->entry; as_bad (_("Unknown exception: `%s'"), s); return 0; } /* Post-Increment instructions, as well as Store-Immediate instructions, are a sub-group within load/stor instruction groups. Therefore, when parsing a Post-Increment/Store-Immediate insn, we have to advance the instruction pointer to the start of that sub-group (that is, up to the first instruction of that type). Otherwise, the insn will be mistakenly identified as of type LD_STOR_INS. */ static void handle_LoadStor (char *operands) { /* Post-Increment instructions precede Store-Immediate instructions in CRX instruction table, hence they are handled before. This synchronization should be kept. */ /* Assuming Post-Increment insn has the following format : 'MNEMONIC DISP(REG)+, REG' (e.g. 'loadw 12(r5)+, r6'). LD_STOR_INS_INC are the only store insns containing a plus sign (+). */ if (strstr (operands, ")+") != NULL) { while (! IS_INSN_TYPE (LD_STOR_INS_INC)) instruction++; return; } /* Assuming Store-Immediate insn has the following format : 'MNEMONIC $DISP, ...' (e.g. 'storb $1, 12(r5)'). STOR_IMM_INS are the only store insns containing a dollar sign ($). */ if (strstr (operands, "$") != NULL) while (! IS_INSN_TYPE (STOR_IMM_INS)) instruction++; } /* Top level module where instruction parsing starts. crx_ins - data structure holds some information. operands - holds the operands part of the whole instruction. */ static void parse_insn (ins *insn, char *operands) { int i; /* Handle instructions with no operands. */ for (i = 0; no_op_insn[i] != NULL; i++) { if (streq (no_op_insn[i], instruction->mnemonic)) { insn->nargs = 0; return; } } /* Handle 'excp'/'cinv' instructions. */ if (IS_INSN_MNEMONIC ("excp") || IS_INSN_MNEMONIC ("cinv")) { insn->nargs = 1; insn->arg[0].type = arg_ic; insn->arg[0].constant = IS_INSN_MNEMONIC ("excp") ? gettrap (operands) : get_cinv_parameters (operands); insn->arg[0].X_op = O_constant; return; } /* Handle load/stor unique instructions before parsing. */ if (IS_INSN_TYPE (LD_STOR_INS)) handle_LoadStor (operands); if (operands != NULL) parse_operands (insn, operands); } /* Cinv instruction requires special handling. */ static int get_cinv_parameters (char * operand) { char *p = operand; int d_used = 0, i_used = 0, u_used = 0, b_used = 0; while (*++p != ']') { if (*p == ',' || *p == ' ') continue; if (*p == 'd') d_used = 1; else if (*p == 'i') i_used = 1; else if (*p == 'u') u_used = 1; else if (*p == 'b') b_used = 1; else as_bad (_("Illegal `cinv' parameter: `%c'"), *p); } return ((b_used ? 8 : 0) + (d_used ? 4 : 0) + (i_used ? 2 : 0) + (u_used ? 1 : 0)); } /* Retrieve the opcode image of a given register. If the register is illegal for the current instruction, issue an error. */ static int getreg_image (reg r) { const reg_entry *reg; char *reg_name; int is_procreg = 0; /* Nonzero means argument should be processor reg. */ if (((IS_INSN_MNEMONIC ("mtpr")) && (cur_arg_num == 1)) || ((IS_INSN_MNEMONIC ("mfpr")) && (cur_arg_num == 0)) ) is_procreg = 1; /* Check whether the register is in registers table. */ if (r < MAX_REG) reg = &crx_regtab[r]; /* Check whether the register is in coprocessor registers table. */ else if (r < MAX_COPREG) reg = &crx_copregtab[r-MAX_REG]; /* Register not found. */ else { as_bad (_("Unknown register: `%d'"), r); return 0; } reg_name = reg->name; /* Issue a error message when register is illegal. */ #define IMAGE_ERR \ as_bad (_("Illegal register (`%s') in Instruction: `%s'"), \ reg_name, ins_parse); \ break; switch (reg->type) { case CRX_U_REGTYPE: if (is_procreg || (instruction->flags & USER_REG)) return reg->image; else IMAGE_ERR; case CRX_CFG_REGTYPE: if (is_procreg) return reg->image; else IMAGE_ERR; case CRX_R_REGTYPE: if (! is_procreg) return reg->image; else IMAGE_ERR; case CRX_C_REGTYPE: case CRX_CS_REGTYPE: return reg->image; break; default: IMAGE_ERR; } return 0; } /* Routine used to represent integer X using NBITS bits. */ static long getconstant (long x, int nbits) { /* The following expression avoids overflow if 'nbits' is the number of bits in 'bfd_vma'. */ return (x & ((((1 << (nbits - 1)) - 1) << 1) | 1)); } /* Print a constant value to 'output_opcode': ARG holds the operand's type and value. SHIFT represents the location of the operand to be print into. NBITS determines the size (in bits) of the constant. */ static void print_constant (int nbits, int shift, argument *arg) { unsigned long mask = 0; long constant = getconstant (arg->constant, nbits); switch (nbits) { case 32: case 28: case 24: case 22: /* mask the upper part of the constant, that is, the bits going to the lowest byte of output_opcode[0]. The upper part of output_opcode[1] is always filled, therefore it is always masked with 0xFFFF. */ mask = (1 << (nbits - 16)) - 1; /* Divide the constant between two consecutive words : 0 1 2 3 +---------+---------+---------+---------+ | | X X X X | X X X X | | +---------+---------+---------+---------+ output_opcode[0] output_opcode[1] */ CRX_PRINT (0, (constant >> WORD_SHIFT) & mask, 0); CRX_PRINT (1, (constant & 0xFFFF), WORD_SHIFT); break; case 16: case 12: /* Special case - in arg_cr, the SHIFT represents the location of the REGISTER, not the constant, which is itself not shifted. */ if (arg->type == arg_cr) { CRX_PRINT (0, constant, 0); break; } /* When instruction size is 3 and 'shift' is 16, a 16-bit constant is always filling the upper part of output_opcode[1]. If we mistakenly write it to output_opcode[0], the constant prefix (that is, 'match') will be overridden. 0 1 2 3 +---------+---------+---------+---------+ | 'match' | | X X X X | | +---------+---------+---------+---------+ output_opcode[0] output_opcode[1] */ if ((instruction->size > 2) && (shift == WORD_SHIFT)) CRX_PRINT (1, constant, WORD_SHIFT); else CRX_PRINT (0, constant, shift); break; default: CRX_PRINT (0, constant, shift); break; } } /* Print an operand to 'output_opcode', which later on will be printed to the object file: ARG holds the operand's type, size and value. SHIFT represents the printing location of operand. NBITS determines the size (in bits) of a constant operand. */ static void print_operand (int nbits, int shift, argument *arg) { switch (arg->type) { case arg_r: CRX_PRINT (0, getreg_image (arg->r), shift); break; case arg_copr: if (arg->cr < c0 || arg->cr > c15) as_bad (_("Illegal Co-processor register in Instruction `%s' "), ins_parse); CRX_PRINT (0, getreg_image (arg->cr), shift); break; case arg_copsr: if (arg->cr < cs0 || arg->cr > cs15) as_bad (_("Illegal Co-processor special register in Instruction `%s' "), ins_parse); CRX_PRINT (0, getreg_image (arg->cr), shift); break; case arg_idxr: /* 16 12 8 6 0 +--------------------------------+ | r_base | r_idx | scl| disp | +--------------------------------+ */ CRX_PRINT (0, getreg_image (arg->r), 12); CRX_PRINT (0, getreg_image (arg->i_r), 8); CRX_PRINT (0, arg->scale, 6); case arg_ic: case arg_c: print_constant (nbits, shift, arg); break; case arg_rbase: CRX_PRINT (0, getreg_image (arg->r), shift); break; case arg_cr: /* case base_cst4. */ if (instruction->flags & DISPU4MAP) print_constant (nbits, shift + REG_SIZE, arg); else /* rbase_disps<NN> and other such cases. */ print_constant (nbits, shift, arg); /* Add the register argument to the output_opcode. */ CRX_PRINT (0, getreg_image (arg->r), shift); break; default: break; } } /* Retrieve the number of operands for the current assembled instruction. */ static int get_number_of_operands (void) { int i; for (i = 0; instruction->operands[i].op_type && i < MAX_OPERANDS; i++) ; return i; } /* Verify that the number NUM can be represented in BITS bits (that is, within its permitted range), based on the instruction's FLAGS. If UPDATE is nonzero, update the value of NUM if necessary. Return OP_LEGAL upon success, actual error type upon failure. */ static op_err check_range (long *num, int bits, int unsigned flags, int update) { long min, max; int retval = OP_LEGAL; int bin; long upper_64kb = 0xFFFF0000; long value = *num; /* For hosts witah longs bigger than 32-bits make sure that the top bits of a 32-bit negative value read in by the parser are set, so that the correct comparisons are made. */ if (value & 0x80000000) value |= (-1L << 31); /* Verify operand value is even. */ if (flags & OP_EVEN) { if (value % 2) return OP_NOT_EVEN; } if (flags & OP_UPPER_64KB) { /* Check if value is to be mapped to upper 64 KB memory area. */ if ((value & upper_64kb) == upper_64kb) { value -= upper_64kb; if (update) *num = value; } else return OP_NOT_UPPER_64KB; } if (flags & OP_SHIFT) { value >>= 1; if (update) *num = value; } else if (flags & OP_SHIFT_DEC) { value = (value >> 1) - 1; if (update) *num = value; } if (flags & OP_ESC) { /* 0x7e and 0x7f are reserved escape sequences of dispe9. */ if (value == 0x7e || value == 0x7f) return OP_OUT_OF_RANGE; } if (flags & OP_DISPU4) { int is_dispu4 = 0; int mul = (instruction->flags & DISPUB4) ? 1 : (instruction->flags & DISPUW4) ? 2 : (instruction->flags & DISPUD4) ? 4 : 0; for (bin = 0; bin < cst4_maps; bin++) { if (value == (mul * bin)) { is_dispu4 = 1; if (update) *num = bin; break; } } if (!is_dispu4) retval = OP_ILLEGAL_DISPU4; } else if (flags & OP_CST4) { int is_cst4 = 0; for (bin = 0; bin < cst4_maps; bin++) { if (value == cst4_map[bin]) { is_cst4 = 1; if (update) *num = bin; break; } } if (!is_cst4) retval = OP_ILLEGAL_CST4; } else if (flags & OP_SIGNED) { max = (1 << (bits - 1)) - 1; min = - (1 << (bits - 1)); if ((value > max) || (value < min)) retval = OP_OUT_OF_RANGE; } else if (flags & OP_UNSIGNED) { max = ((((1 << (bits - 1)) - 1) << 1) | 1); min = 0; if (((unsigned long) value > (unsigned long) max) || ((unsigned long) value < (unsigned long) min)) retval = OP_OUT_OF_RANGE; } return retval; } /* Assemble a single instruction: INSN is already parsed (that is, all operand values and types are set). For instruction to be assembled, we need to find an appropriate template in the instruction table, meeting the following conditions: 1: Has the same number of operands. 2: Has the same operand types. 3: Each operand size is sufficient to represent the instruction's values. Returns 1 upon success, 0 upon failure. */ static int assemble_insn (char *mnemonic, ins *insn) { /* Type of each operand in the current template. */ argtype cur_type[MAX_OPERANDS]; /* Size (in bits) of each operand in the current template. */ unsigned int cur_size[MAX_OPERANDS]; /* Flags of each operand in the current template. */ unsigned int cur_flags[MAX_OPERANDS]; /* Instruction type to match. */ unsigned int ins_type; /* Boolean flag to mark whether a match was found. */ int match = 0; int i; /* Nonzero if an instruction with same number of operands was found. */ int found_same_number_of_operands = 0; /* Nonzero if an instruction with same argument types was found. */ int found_same_argument_types = 0; /* Nonzero if a constant was found within the required range. */ int found_const_within_range = 0; /* Argument number of an operand with invalid type. */ int invalid_optype = -1; /* Argument number of an operand with invalid constant value. */ int invalid_const = -1; /* Operand error (used for issuing various constant error messages). */ op_err op_error, const_err = OP_LEGAL; /* Retrieve data (based on FUNC) for each operand of a given instruction. */ #define GET_CURRENT_DATA(FUNC, ARRAY) \ for (i = 0; i < insn->nargs; i++) \ ARRAY[i] = FUNC (instruction->operands[i].op_type) #define GET_CURRENT_TYPE GET_CURRENT_DATA(get_optype, cur_type) #define GET_CURRENT_SIZE GET_CURRENT_DATA(get_opbits, cur_size) #define GET_CURRENT_FLAGS GET_CURRENT_DATA(get_opflags, cur_flags) /* Instruction has no operands -> only copy the constant opcode. */ if (insn->nargs == 0) { output_opcode[0] = BIN (instruction->match, instruction->match_bits); return 1; } /* In some case, same mnemonic can appear with different instruction types. For example, 'storb' is supported with 3 different types : LD_STOR_INS, LD_STOR_INS_INC, STOR_IMM_INS. We assume that when reaching this point, the instruction type was pre-determined. We need to make sure that the type stays the same during a search for matching instruction. */ ins_type = CRX_INS_TYPE(instruction->flags); while (/* Check that match is still not found. */ match != 1 /* Check we didn't get to end of table. */ && instruction->mnemonic != NULL /* Check that the actual mnemonic is still available. */ && IS_INSN_MNEMONIC (mnemonic) /* Check that the instruction type wasn't changed. */ && IS_INSN_TYPE(ins_type)) { /* Check whether number of arguments is legal. */ if (get_number_of_operands () != insn->nargs) goto next_insn; found_same_number_of_operands = 1; /* Initialize arrays with data of each operand in current template. */ GET_CURRENT_TYPE; GET_CURRENT_SIZE; GET_CURRENT_FLAGS; /* Check for type compatibility. */ for (i = 0; i < insn->nargs; i++) { if (cur_type[i] != insn->arg[i].type) { if (invalid_optype == -1) invalid_optype = i + 1; goto next_insn; } } found_same_argument_types = 1; for (i = 0; i < insn->nargs; i++) { /* Reverse the operand indices for certain opcodes: Index 0 -->> 1 Index 1 -->> 0 Other index -->> stays the same. */ int j = instruction->flags & REVERSE_MATCH ? i == 0 ? 1 : i == 1 ? 0 : i : i; /* Only check range - don't update the constant's value, since the current instruction may not be the last we try to match. The constant's value will be updated later, right before printing it to the object file. */ if ((insn->arg[j].X_op == O_constant) && (op_error = check_range (&insn->arg[j].constant, cur_size[j], cur_flags[j], 0))) { if (invalid_const == -1) { invalid_const = j + 1; const_err = op_error; } goto next_insn; } /* For symbols, we make sure the relocation size (which was already determined) is sufficient. */ else if ((insn->arg[j].X_op == O_symbol) && ((bfd_reloc_type_lookup (stdoutput, insn->rtype))->bitsize > cur_size[j])) goto next_insn; } found_const_within_range = 1; /* If we got till here -> Full match is found. */ match = 1; break; /* Try again with next instruction. */ next_insn: instruction++; } if (!match) { /* We haven't found a match - instruction can't be assembled. */ if (!found_same_number_of_operands) as_bad (_("Incorrect number of operands")); else if (!found_same_argument_types) as_bad (_("Illegal type of operand (arg %d)"), invalid_optype); else if (!found_const_within_range) { switch (const_err) { case OP_OUT_OF_RANGE: as_bad (_("Operand out of range (arg %d)"), invalid_const); break; case OP_NOT_EVEN: as_bad (_("Operand has odd displacement (arg %d)"), invalid_const); break; case OP_ILLEGAL_DISPU4: as_bad (_("Invalid DISPU4 operand value (arg %d)"), invalid_const); break; case OP_ILLEGAL_CST4: as_bad (_("Invalid CST4 operand value (arg %d)"), invalid_const); break; case OP_NOT_UPPER_64KB: as_bad (_("Operand value is not within upper 64 KB (arg %d)"), invalid_const); break; default: as_bad (_("Illegal operand (arg %d)"), invalid_const); break; } } return 0; } else /* Full match - print the encoding to output file. */ { /* Make further checkings (such that couldn't be made earlier). Warn the user if necessary. */ warn_if_needed (insn); /* Check whether we need to adjust the instruction pointer. */ if (adjust_if_needed (insn)) /* If instruction pointer was adjusted, we need to update the size of the current template operands. */ GET_CURRENT_SIZE; for (i = 0; i < insn->nargs; i++) { int j = instruction->flags & REVERSE_MATCH ? i == 0 ? 1 : i == 1 ? 0 : i : i; /* This time, update constant value before printing it. */ if ((insn->arg[j].X_op == O_constant) && (check_range (&insn->arg[j].constant, cur_size[j], cur_flags[j], 1) != OP_LEGAL)) as_fatal (_("Illegal operand (arg %d)"), j+1); } /* First, copy the instruction's opcode. */ output_opcode[0] = BIN (instruction->match, instruction->match_bits); for (i = 0; i < insn->nargs; i++) { cur_arg_num = i; print_operand (cur_size[i], instruction->operands[i].shift, &insn->arg[i]); } } return 1; } /* Bunch of error checkings. The checks are made after a matching instruction was found. */ void warn_if_needed (ins *insn) { /* If the post-increment address mode is used and the load/store source register is the same as rbase, the result of the instruction is undefined. */ if (IS_INSN_TYPE (LD_STOR_INS_INC)) { /* Enough to verify that one of the arguments is a simple reg. */ if ((insn->arg[0].type == arg_r) || (insn->arg[1].type == arg_r)) if (insn->arg[0].r == insn->arg[1].r) as_bad (_("Same src/dest register is used (`r%d'), result is undefined"), insn->arg[0].r); } /* Some instruction assume the stack pointer as rptr operand. Issue an error when the register to be loaded is also SP. */ if (instruction->flags & NO_SP) { if (getreg_image (insn->arg[0].r) == getreg_image (sp)) as_bad (_("`%s' has undefined result"), ins_parse); } /* If the rptr register is specified as one of the registers to be loaded, the final contents of rptr are undefined. Thus, we issue an error. */ if (instruction->flags & NO_RPTR) { if ((1 << getreg_image (insn->arg[0].r)) & insn->arg[1].constant) as_bad (_("Same src/dest register is used (`r%d'), result is undefined"), getreg_image (insn->arg[0].r)); } } /* In some cases, we need to adjust the instruction pointer although a match was already found. Here, we gather all these cases. Returns 1 if instruction pointer was adjusted, otherwise 0. */ int adjust_if_needed (ins *insn) { int ret_value = 0; /* Special check for 'addub $0, r0' instruction - The opcode '0000 0000 0000 0000' is not allowed. */ if (IS_INSN_MNEMONIC ("addub")) { if ((instruction->operands[0].op_type == cst4) && instruction->operands[1].op_type == regr) { if (insn->arg[0].constant == 0 && insn->arg[1].r == r0) { instruction++; ret_value = 1; } } } /* Optimization: Omit a zero displacement in bit operations, saving 2-byte encoding space (e.g., 'cbitw $8, 0(r1)'). */ if (IS_INSN_TYPE (CSTBIT_INS)) { if ((instruction->operands[1].op_type == rbase_disps12) && (insn->arg[1].X_op == O_constant) && (insn->arg[1].constant == 0)) { instruction--; ret_value = 1; } } return ret_value; } /* Set the appropriate bit for register 'r' in 'mask'. This indicates that this register is loaded or stored by the instruction. */ static void mask_reg (int r, unsigned short int *mask) { if ((reg)r > (reg)sp) { as_bad (_("Invalid Register in Register List")); return; } *mask |= (1 << r); } /* Preprocess register list - create a 16-bit mask with one bit for each of the 16 general purpose registers. If a bit is set, it indicates that this register is loaded or stored by the instruction. */ static char * preprocess_reglist (char *param, int *allocated) { char reg_name[MAX_REGNAME_LEN]; /* Current parsed register name. */ char *regP; /* Pointer to 'reg_name' string. */ int reg_counter = 0; /* Count number of parsed registers. */ unsigned short int mask = 0; /* Mask for 16 general purpose registers. */ char *new_param; /* New created operands string. */ char *paramP = param; /* Pointer to original opearands string. */ char maskstring[10]; /* Array to print the mask as a string. */ int hi_found = 0, lo_found = 0; /* Boolean flags for hi/lo registers. */ reg r; copreg cr; /* If 'param' is already in form of a number, no need to preprocess. */ if (strchr (paramP, '{') == NULL) return param; /* Verifying correct syntax of operand. */ if (strchr (paramP, '}') == NULL) as_fatal (_("Missing matching brackets : `%s'"), ins_parse); while (*paramP++ != '{'); new_param = (char *)xcalloc (MAX_INST_LEN, sizeof (char)); *allocated = 1; strncpy (new_param, param, paramP - param - 1); while (*paramP != '}') { regP = paramP; memset (®_name, '\0', sizeof (reg_name)); while (ISALNUM (*paramP)) paramP++; strncpy (reg_name, regP, paramP - regP); /* Coprocessor register c<N>. */ if (IS_INSN_TYPE (COP_REG_INS)) { if (((cr = get_copregister (reg_name)) == nullcopregister) || (crx_copregtab[cr-MAX_REG].type != CRX_C_REGTYPE)) as_fatal (_("Illegal register `%s' in cop-register list"), reg_name); mask_reg (getreg_image (cr - c0), &mask); } /* Coprocessor Special register cs<N>. */ else if (IS_INSN_TYPE (COPS_REG_INS)) { if (((cr = get_copregister (reg_name)) == nullcopregister) || (crx_copregtab[cr-MAX_REG].type != CRX_CS_REGTYPE)) as_fatal (_("Illegal register `%s' in cop-special-register list"), reg_name); mask_reg (getreg_image (cr - cs0), &mask); } /* User register u<N>. */ else if (instruction->flags & USER_REG) { if (streq(reg_name, "uhi")) { hi_found = 1; goto next_inst; } else if (streq(reg_name, "ulo")) { lo_found = 1; goto next_inst; } else if (((r = get_register (reg_name)) == nullregister) || (crx_regtab[r].type != CRX_U_REGTYPE)) as_fatal (_("Illegal register `%s' in user register list"), reg_name); mask_reg (getreg_image (r - u0), &mask); } /* General purpose register r<N>. */ else { if (streq(reg_name, "hi")) { hi_found = 1; goto next_inst; } else if (streq(reg_name, "lo")) { lo_found = 1; goto next_inst; } else if (((r = get_register (reg_name)) == nullregister) || (crx_regtab[r].type != CRX_R_REGTYPE)) as_fatal (_("Illegal register `%s' in register list"), reg_name); mask_reg (getreg_image (r - r0), &mask); } if (++reg_counter > MAX_REGS_IN_MASK16) as_bad (_("Maximum %d bits may be set in `mask16' operand"), MAX_REGS_IN_MASK16); next_inst: while (!ISALNUM (*paramP) && *paramP != '}') paramP++; } if (*++paramP != '\0') as_warn (_("rest of line ignored; first ignored character is `%c'"), *paramP); switch (hi_found + lo_found) { case 0: /* At least one register should be specified. */ if (mask == 0) as_bad (_("Illegal `mask16' operand, operation is undefined - `%s'"), ins_parse); break; case 1: /* HI can't be specified without LO (and vise-versa). */ as_bad (_("HI/LO registers should be specified together")); break; case 2: /* HI/LO registers mustn't be masked with additional registers. */ if (mask != 0) as_bad (_("HI/LO registers should be specified without additional registers")); default: break; } sprintf (maskstring, "$0x%x", mask); strcat (new_param, maskstring); return new_param; } /* Print the instruction. Handle also cases where the instruction is relaxable/relocatable. */ void print_insn (ins *insn) { unsigned int i, j, insn_size; char *this_frag; unsigned short words[4]; int addr_mod; /* Arrange the insn encodings in a WORD size array. */ for (i = 0, j = 0; i < 2; i++) { words[j++] = (output_opcode[i] >> 16) & 0xFFFF; words[j++] = output_opcode[i] & 0xFFFF; } /* Handle relaxtion. */ if ((instruction->flags & RELAXABLE) && relocatable) { int relax_subtype; /* Write the maximal instruction size supported. */ insn_size = INSN_MAX_SIZE; /* bCC */ if (IS_INSN_TYPE (BRANCH_INS)) relax_subtype = 0; /* bal */ else if (IS_INSN_TYPE (DCR_BRANCH_INS) || IS_INSN_MNEMONIC ("bal")) relax_subtype = 3; /* cmpbr/bcop */ else if (IS_INSN_TYPE (CMPBR_INS) || IS_INSN_TYPE (COP_BRANCH_INS)) relax_subtype = 5; else abort (); this_frag = frag_var (rs_machine_dependent, insn_size * 2, 4, relax_subtype, insn->exp.X_add_symbol, insn->exp.X_add_number, 0); } else { insn_size = instruction->size; this_frag = frag_more (insn_size * 2); /* Handle relocation. */ if ((relocatable) && (insn->rtype != BFD_RELOC_NONE)) { reloc_howto_type *reloc_howto; int size; reloc_howto = bfd_reloc_type_lookup (stdoutput, insn->rtype); if (!reloc_howto) abort (); size = bfd_get_reloc_size (reloc_howto); if (size < 1 || size > 4) abort (); fix_new_exp (frag_now, this_frag - frag_now->fr_literal, size, &insn->exp, reloc_howto->pc_relative, insn->rtype); } } /* Verify a 2-byte code alignment. */ addr_mod = frag_now_fix () & 1; if (frag_now->has_code && frag_now->insn_addr != addr_mod) as_bad (_("instruction address is not a multiple of 2")); frag_now->insn_addr = addr_mod; frag_now->has_code = 1; /* Write the instruction encoding to frag. */ for (i = 0; i < insn_size; i++) { md_number_to_chars (this_frag, (valueT) words[i], 2); this_frag += 2; } } /* This is the guts of the machine-dependent assembler. OP points to a machine dependent instruction. This function is supposed to emit the frags/bytes it assembles to. */ void md_assemble (char *op) { ins crx_ins; char *param; char c; /* Reset global variables for a new instruction. */ reset_vars (op); /* Strip the mnemonic. */ for (param = op; *param != 0 && !ISSPACE (*param); param++) ; c = *param; *param++ = '\0'; /* Find the instruction. */ instruction = (const inst *) hash_find (crx_inst_hash, op); if (instruction == NULL) { as_bad (_("Unknown opcode: `%s'"), op); return; } /* Tie dwarf2 debug info to the address at the start of the insn. */ dwarf2_emit_insn (0); /* Parse the instruction's operands. */ parse_insn (&crx_ins, param); /* Assemble the instruction - return upon failure. */ if (assemble_insn (op, &crx_ins) == 0) return; /* Print the instruction. */ print_insn (&crx_ins); }
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